Magnetic control of tokamak plasmas through deep reinforcement learning

Author:

Degrave JonasORCID,Felici FedericoORCID,Buchli Jonas,Neunert MichaelORCID,Tracey BrendanORCID,Carpanese Francesco,Ewalds Timo,Hafner RolandORCID,Abdolmaleki Abbas,de las Casas Diego,Donner Craig,Fritz Leslie,Galperti Cristian,Huber AndreaORCID,Keeling James,Tsimpoukelli Maria,Kay Jackie,Merle Antoine,Moret Jean-Marc,Noury Seb,Pesamosca Federico,Pfau David,Sauter Olivier,Sommariva Cristian,Coda Stefano,Duval Basil,Fasoli Ambrogio,Kohli Pushmeet,Kavukcuoglu Koray,Hassabis DemisORCID,Riedmiller MartinORCID

Abstract

AbstractNuclear fusion using magnetic confinement, in particular in the tokamak configuration, is a promising path towards sustainable energy. A core challenge is to shape and maintain a high-temperature plasma within the tokamak vessel. This requires high-dimensional, high-frequency, closed-loop control using magnetic actuator coils, further complicated by the diverse requirements across a wide range of plasma configurations. In this work, we introduce a previously undescribed architecture for tokamak magnetic controller design that autonomously learns to command the full set of control coils. This architecture meets control objectives specified at a high level, at the same time satisfying physical and operational constraints. This approach has unprecedented flexibility and generality in problem specification and yields a notable reduction in design effort to produce new plasma configurations. We successfully produce and control a diverse set of plasma configurations on the Tokamak à Configuration Variable1,2, including elongated, conventional shapes, as well as advanced configurations, such as negative triangularity and ‘snowflake’ configurations. Our approach achieves accurate tracking of the location, current and shape for these configurations. We also demonstrate sustained ‘droplets’ on TCV, in which two separate plasmas are maintained simultaneously within the vessel. This represents a notable advance for tokamak feedback control, showing the potential of reinforcement learning to accelerate research in the fusion domain, and is one of the most challenging real-world systems to which reinforcement learning has been applied.

Publisher

Springer Science and Business Media LLC

Subject

Multidisciplinary

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